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Transcript
Eaton Wiring Manual 06/11
Pilot devices
Page
RMQ – System
3-2
RMQ – Engineering
3-9
RMQ – Inscription
3-13
Signal Towers SL
3-14
LS-Titan®
3-16
position switches
LSE-Titan® electronic position switches
3-26
Analog electronic position switches
3-27
Sensors – Functionality
3-30
Sensors – Applications
3-37
3-1
33
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
33
Commands and signals are the
fundamental functions for controlling
machines and processes. The required
control signals are produced either
manually by pilot devices or mechanically
by position switches. The respective
application governs the protection type,
the shape and color.
Advanced technology has been used
consistently in control circuit devices
„RMQ-Titan®“ . The use of LED elements
and laser inscription throughout offer
maximum reliability, efficiency and
flexibility. In detail, this means:
• High-quality optics for a uniform
appearance,
• Highest degree of protection up to IP67
and IP69K (suitable for steam-jet
cleaning),
• Clear contrast using LED element
lighting, even in daylight,
• Up to 100,000 h, i.e. machine lifespan,
• Impact and vibration resistant,
• LED operating voltage from 12 to 500 V,
• Low power consumption – only 1/6 of
filament lamps,
• Expanded operating temperature range
-25 to +70 °C,
• Light testing circuit,
• Built-in safety circuits for highest
operational reliability and accessibility,
• wear-resistant and clearly contrasting
laser inscription,
• Customer-specific symbols and
inscriptions from 1 off,
• Text and symbols can be freely
combined,
• Terminal type using screws and Cage
Clamp1) throughout,
3-2
• Spring-loaded Cage Clamp connections
for reliable and maintenance free
contact,
• Switching contacts suitable for use with
electronic devices to EN 61131-2:
5 V/1 mA,
• user-programmable switching
performance on all selector switch
actuators: momentary/maintained
• All actuators in illuminated and
non-illuminated version,
• Emergency switching off pushbuttons
with pull and turn-to-release function,
• Emergency switching off pushbuttons
with lighting option for active safety,
• Contacts switch differing potentials,
• For use also in safety-related circuits
using positive operation and positive
opening contacts,
• Complying with industry Standard
IEC/EN60947.
1)
Cage Clamp is a registered trade mark of
Messrs. WAGO Kontakttechnik GmbH, Minden
RMQ16 system overview
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
RMQ-Titan® system overview
33
3-3
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
33
Four-way pushbutton
Eaton has added more operator elements
to its highly successful range of pilot
devices RMQ-Titan. It has a modular
surface mounting. Contact elements from
the RMQ-Titan range are used. The bezels
and front frames are of the familiar
RMQ-Titan format and color.
Four-way pushbutton
The four-way pushbuttons enable users to
control machines and systems in four
directions of movement. Each direction of
movement is being assigned one contact
element. The pushbutton has four
individual button plates. They can be
specifically selected for various
applications and can be laser-inscribed to
suit the customer's requirements.
Joystick with double contact
The joystick allows the control of up to four
directions of movement on machines.
Different variants of the joystick have 2/4
positions and other variants have 2 settings
for each position. This allows for example
two speed settings for each direction. For
this a standard NO and an NO early-make
are fitted in series. Momentary contact and
latching contact versions are possible.
0
0
1
1
2
Selector switch actuators
The selector switch actuators have four
positions. The actuator is available either
as a rotary head or as a thumb-grip. One
contact element is assigned to each On
and each Off position.
3-4
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
Labels
Eaton offers various types of labels for all
operating elements. Versions available
are:
• Blank,
• With direction arrows,
• With inscription 0–1–0–2–0–3–0–4.
Customised inscriptions are also possible.
The software Labeleditor enables
customized inscriptions to be designed and
these can be subsequently applied to the
labels by laser, permanently and proof
against wiping off. → Section
”Labeleditor”, page 3-13
33
Contact versions
Screw
terminals
Springloaded
terminals
Front
fixing
Base fixing
x
x
Contact
Contact travel
diagram1)
Contact elements
x
x
.3
0
2.8
5.5
.4
M22-(C)K(C)10
x
x
x
–
.1
0 1.2
5.5
.2
M22-(C)K(C)01
x
x
x
x
.5
0
3.5
5.5
.6
M22-(C)K01D2)
x
–
x
–
.7
0
1.8
5.5
.8
M22-K10P
1) Stroke in connection with front element.
2) N/C: Positive opening safety function according to IEC/EN 60947-5-1.
3-5
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
Screw
terminals
Springloaded
terminals
Front
fixing
Base fixing
x
–
Contact
Contact travel
diagram1)
Double contact elements
–
x
33
.3
.3
.4
.4
0
3.6
5.5
M22-CK20
–
x
x
–
.1
.1
.2
.2
0 1.2
5.5
M22-CK02
–
x
x
–
.1
.3
.2
.4
0 1.2 3.6
5.5
M22-CK112)
Self-monitoring contact elements
x
–
x
x
3
1
4
2
0 1.2
2.8
5.5
M22-K(C)01SMC10
x
–
x
x
3
1
1
4
2
2
0 1.2
2.8
5.5
M22-K(C)02SMC10
1) Stroke in connection with front element.
2) N/C: Positive opening safety function according to IEC/EN 60947-5-1.
3-6
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
Mushroom-shaped
Emergency-stop/off pushbuttons, system overview
38
33
45
EME
RGENCY
O
-ST
P
Palm-tree shape
60
3-7
Eaton Wiring Manual 06/11
Pilot devices
RMQ – System
33
The new emergency stop or emergency-off
pushbutton actuators for the RMQ-Titan
range of pilot devices for global use have a
palm shaped design with a 45 or 60 mm
diameter. They are available with or
without keys, turn-releasable,
non-illuminated, illuminated with standard
LEDs or with mechanical switch position
indication (green/red) in the center of the
actuator element. The self-monitoring
contact elements ensure extensive
operational safety; even with a faulty
installation or after excessive force is used
for actuation. As well as the emergency-off
NC contact, the modular contact elements
feature an integrated second contact for
querying the mechanical connection to the
emergency stop actuator element. The
contact elements are available for front or
bottom fixing, for single or dual-channel
safety circuits up to SIL 3 in accordance
with IEC 62061 or Performance Level PL e
to EN ISO 13849-1.
3-8
An optional illuminated ring enables
emergency-stop/off pushbutton actuators
on a machine or a plant to be made more
conspicuous. Even in darkened
environments, the position of these
pushbutton actuators is clearly indicated.
The illuminated ring also clearly indicates
the operating state from a considerable
distance. When tripped, for example, it is
possible to activate three separately
controllable LED rows as a running light.
Eaton Wiring Manual 06/11
Pilot devices
RMQ – Engineering
Assembly and function
M22…SMC10
M22-PV...
33
a
a
M22-K... SMC10
b
b
M22-K... SMC10
a The self-monitoring contact mechanically monitors the connection on the M22-PV…
b The self-monitoring contact mechanically monitors the interface on the
M22-K…SMC10 safety contact above it; but NOT the connection on the M22-PV…
M22-K01SMC10
M22-KC01SMC10
M22-K02SMC10
M22-KC02SMC10
3
1
3
1
1
4
2
4
2
2
When the self-monitoring contact is mounted correctly, the N/O contact is closed.
The emergency switching off/Stop circuit is activated via series connection of N/C and
N/Os if
• the emergency switching off/stop pushbutton is actuated or
• the self-monitoring contact is isolated mechanically from the pushbutton
3-9
Eaton Wiring Manual 06/11
Pilot devices
RMQ – Engineering
Terminal markings and function numbers (distinctive number/contact sequence),
EN 50013
10
01
13
14
33
20
30
21
22
11
13
21
24
14
22
13
23
33
21
13
21
33
14
24
34
14
22
34
13
23
14
12
13
21
31
14
22
32
02
11
21
12
22
03
11
21
31
12
22
32
Voltage variants with series elements
Ue h/H
12 – 30 V h/H
1
2
1
2
1
2
X1
X2
M22-(C)LED(C)-...
M22-XLED60/
M22-XLED220
85 – 264 V h,
50 – 60 Hz
2
1
2
M22-XLED230-T
3-10
Ue ≦AC/DC
1x
60 V
2x
90 V
3x
120 V
...
...
7x
240 V
M22-XLED220
Ue ≦
1x
220 V DC
1) For increasing the voltage
AC/DC.
Ue h
1
M22-XLED601)
X1
X2
M22-(C)LED(C)230-...
M22-XLED230-T1)
Ue ≦
1x
400 V~
2x
500 V~
1) AC– for increasing the voltage
50/60 Hz.
Eaton Wiring Manual 06/11
Pilot devices
RMQ – Engineering
Connection for light test
The test button is used to check operation
of the indicator lights independently of the
respective control state. Decoupling
elements prevent voltage feedback.
M22-XLED-T
for Ue = 12 to 240 V AC/DC (also for light test
with signal towers SL)
13
13
13
14
14
14
2
12 – 240 V h/H
33
a
4
1
2
1
2
1
2
1
3
1
M22-XLED60/
M22-XLED220
2
1
M22-XLED60/
M22-XLED220
2
1
1
M22-XLED-T
1
M22-XLED60/
M22-XLED220
2
2
2
X1
X1
X1
X2
X2
X2
M22-(C)LED(C)-... 1)
a Test button
1) Only for elements 12 to 30 V.
3-11
Eaton Wiring Manual 06/11
Pilot devices
RMQ – Engineering
M22-XLED230-T
for Ue = 85 to 264 V AC/50 – 60 Hz
L1
85 – 264 V h/50 – 60 Hz
33
13
13
13
14
14
14
2
3
1
4
2
1
2
1
2
1
M22-XLED230-T
X1
X1
X1
X2
X2
X2
N
a Test button
2) For elements 85 to 264 V.
3-12
a
M22-(C)LED(C)230-... 2)
Eaton Wiring Manual 06/11
Pilot devices
RMQ – Inscription
Labeleditor
• Button plate in green with special
inscription
Basic type: M22-XDH-*
1. * = Colour (here „G“ for green),
2.* = File name generated by Labeleditor
Please order:
1 x M22-XDH-G-RMQ_Titan_xxxxx.zip
Customized inscription of devices using
the Labeleditor software
You can label your device to your individual
requirements in four simple steps:
• Download the inscription software:
www.eaton.com/moeller/support
keyword: ”Labeleditor”
• Creation of label template (menu-guided
in the software)
• Send the label template to the factory by
email. The email address is automatically
set for the selected product by the
program. When your template is sent, the
Labeleditor issues a file name such as
“RMQ_Silver_12345.zip”. This file name
is part of the article to be ordered (see
Ordering examples).
• Send order to the Eaton sales office or
the electrical engineering wholesaling.
Ordering examples
• M22-XST insert label for M22S-ST-X
legend label mount with special
inscription
Basic type: M22-XST-*
33
• Double actuator pushbutton with white
pushbutton plates and special symbols
Basic type: M22-DDL-*-*-*
1. * = Colour (here „W“ for white),
2. and 3. * = File name assigned by
Labeleditor; must be stated here 2 x
Please order:
1 x M22-DDL-W-RMQ_Titan_xx
xxx.zip-RMQ_Titan_xxxxx.zip
• Key-operated button, 2 positions,
individual lock mechanism no. MS1,
individual symbol
Basic type: M22-WRS*-MS*-*
WRS*: * = Number of positions,
MS*: * = Number of individual lock
mechanism,
-*: * = File name assigned in Labeleditor
Please order:
1x
M22-WRS2-MS1-RMQ_Titan_xxxxxx.zip
* = File name generated by Labelditor
Please order:
1 x M22-XST-RMQ_Titan_xxxxxx.zip
3-13
Eaton Wiring Manual 06/11
Pilot devices
Signal Towers SL
Signal Towers SL – everything under visual control at all times
33
Signal towers SL (IP65) indicate machine
states using visible and acoustic signals.
Mounted on control panels or on
machines, they can be reliably recognized
as continuous light, flashing light, strobe
light or acoustic device even from a
distance, and dealt with as necessary.
Product features
• Continuous light, flashing light, strobe
light and acoustic device can be
combined as required.
• Free programmability permits the
actuation of five addresses.
• Simple assembly without tools by
bayonet fitting.
• Automatic contacting by built-in contact
pins.
• Excellent illumination by specially
shaped lenses with Fresnel effect.
• Use of filament lamps or LEDs as
required.
• A large number of complete devices
simplifies selection, ordering and
stockkeeping for standard applications.
The various colors of the light elements
indicate the operating state in each case to
IEC/EN 60204-1 an:
RED:
Dangerous state – Immediate action
necessary
YELLOW:
Abnormal status – monitor or ‐action
GREEN:
Normal status – no action necessary
BLUE:
Discontinuity – action mandatory
WHITE:
Other status – can be used as required.
3-14
Eaton Wiring Manual 06/11
Pilot devices
Signal Towers SL
Programmability
2
1
3
4
0
5
5Ⳏ
33
5
BA15d F 7 W
4Ⳏ
4
3Ⳏ
3
2Ⳏ
1Ⳏ
2
1
054321
N
1...5 Ue = 24 – 230 Vh/Hⵑ
Five signal lines from a terminal strip in the
base module run through each module. The
module is addressed via a wire link
(jumper) on each card. Five different
addresses can also be allocated several
times.
Thus, for example, a red strobe light and in
parallel with it an acoustic device can
indicate and announce the dangerous
status of a machine. Plug both jumpers into
the same position on the pcb – and it's
done!
(→ Section ”Connection for light test”,
page 3-11.)
3-15
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
New combinations for your solutions with LS-Titan®
①
33
LS-Titan
RMQ-Titan
a Operating heads in four positions, each
turned by 90°, can be fitted
subsequently.
Actuating devices RMQ-Titan® simply
snap fitting
Another unique feature is the possibility to
combine actuators from the RMQ-Titan
range with the position switches LS-Titan.
Pushbuttons, selector switches or
emergency switching off pushbuttons can
all be directly snapped on to any position
switch as operating head. The complete
unit then has at least the high protection
type IP66 at front and rear.
3-16
In addition, all the operating heads and the
adapter for accepting the RMQ-Titan
pushbuttons have a bayonet fitting that
enables quick and secure fitting. Using the
bayonet fitting, the heads can be attached
in any of the four directions (4 x 90°).
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
Overview
33
LS, LSM
LS4…ZB
LSR…
LS…ZB
LS…ZBZ
3-17
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
Safety position switches LS4…ZB, LS…ZB
BG
BG
BG
PRÜFZ
ERT
3-18
PRÜFZ
ET 06183
BGIA 0603010
ET 07014
Sicherheit geprüft
tested safety
Sicherheit geprüft
tested safety
Sicherheit geprüft
tested safety
LS4…ZB
LS…ZBZ
PRÜFZ
ERT
Positive opening
Mechanically operated position switches
in safety circuits must have positive
opening contacts (see EN 60947-5-1). Here,
the term positive opening is defined as
follows: “The execution of a contact
separation as the direct result of a
predetermined motion of the keypad of the
switch via non-spring operated parts
(e.g. not dependent on a spring )“.
PRÜFZ
ERT
In addition to these requirements, LS...ZB
position switches offer additional
manipulation safety by means of an
operating head which can rotate but
cannot be removed.
Certification
All Eaton safety position switches are
certified by the employers' liability
insurance Association or by the Technical
Monitoring Service (TÜV), Rheinland.
ERT
“Position switches for safety functions
must be designed so that the safety
function cannot be bypassed manually or
simple tools.” Simple tools are: pliers,
screwdrivers, pins, nails, wire, scissors,
penknives etc.
Positive opening is an opening movement
by which it is ensured that the main
contacts of a switch have attained the
open position at the same time as the
keypad assumes the Off position. Eaton
position switches all meet these
requirements.
BG
33
Eaton safety position switches have been
specially designed for monitoring the
position of protective guards such as
doors, hinged flaps, shrouds and protective
guards. They meet the requirements of the
employers' liability insurance Association
for the testing of positive opening position
switches for safety functions (GS-ET-15).
These requirements include:
ET 06165
Sicherheit geprüft
tested safety
LSR-ZB…
LS…ZB
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
“Personnel protection” by monitoring the protective device
LS…ZB
LS4…ZB
STOP
LS…ZB
closed
• Door open
• LS...ZB
disconnects
power
• No danger
33
Open
a Safety contact
b Signalling contact
a
b
21
22
21
22
13
14
13
14
Door closed
→ Safety contact (21 - 22) closed
Signalling contact (13 - 14) open
Door open
→ Safety contact (21 - 22) open
Signalling contact (13 - 14) closed
3-19
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
„Enhanced personnel protection“ with separate signal for door position
LS…ZBZ
•
•
•
•
Stop command
Waiting time
Machine is stopped
Protective mechanism
open
• No danger
STOP
33
LS…FT-ZBZ, spring-powered interlock
(closed-circuit principle)
LS-S02-…FT-ZBZ
③
a
b
④
a
b
c
d
e
⑤
A1
US
A1
A1
US
A2
21
22
A2
21
22
A2
21
22
11
12
11
12
11
12
Safety contact
Signalling contact
Interlocked
Released
Open
Door closed and
interlocked
→ Coil at (A1, A2) de-energized also with mains failure or wire breakage:
Door interlocked = safe state
Safety contact (21 - 22) closed
Signalling contact (11 - 12) closed
Releasing of door
→ Apply voltage to coil (A1, A2)
e.g. via zero-speed monitor
Safety contact (21 - 22) opens
Signalling contact (11-12) remains closed
Door open
→ Only possible once it is released
Signalling contact (11 - 12) opens.
Door open
→Both contacts in the open position
tamperproof against simple tools
Close door
→ Signalling contact (11 - 12) closes
Lock door
→ Switch off the voltage from coil (A1, A2)
1st actuator interlocked
2nd safety contact (21 - 22) closes
3-20
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
LS-S11-…FT-ZBZ
③
④
A1
A1
A1
A2
21
22
A2
21
22
A2
21
22
13
14
13
14
13
14
Safety contact
Signalling contact
Interlocked
Released
Open
US
US
a
b
a
b
c
d
e
⑤
Door closed and
interlocked
→ Coil at (A1, A2) de-energized also with mains failure or wire breakage:
Door interlocked = safe state
Safety contact (21 - 22) closed
Signalling contact (13 - 14) open
Releasing of door
→ Apply voltage to coil (A1, A2)
e.g. via zero-speed monitor
Safety contact (21 - 22) opens
Signalling contact (13 - 14) remains open
Door open
→ Only possible once it is released
Signalling contact (13 - 14) closes.
Door open
→Safety contact (21 - 22) open
Signalling contact (13 - 14) closed
Close door
→ Signalling contact (13 - 14) opens
Lock door
→ Switch off the voltage from coil (A1, A2)
1st actuator interlocked
2nd safety contact (21 - 22) closes
33
3-21
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
„Process protection and enhanced personnel protection“ with separate signal for door
position
LS…ZBZ
•
•
•
•
Stop command
Waiting time
Process sequence halted
Protective mechanism
open
• Product OK
STOP
33
LS…MT-ZBZ, magnet-powered interlock
(open-circuit principle)
LS-S02-…MT-ZBZ
③
a
b
④
a
b
c
d
e
⑤
A1
US
A1
A1
A2
A2
A2
21
22
21
22
21
22
11
12
11
12
11
12
Safety contact
Signalling contact
Interlocked
Released
Open
Door closed and
interlocked
→ Voltage on coil (A1, A2)
Safety contact (21 - 22) closed
Signalling contact (11 - 12) closed
Releasing of door
→ Coil de-energized (A1, A2)
e.g. via zero-speed monitor,
Safety contact (21 - 22) opens
Signalling contact (11 - 12) remains closed
Door open
→ Only possible once it is released
Signalling contact (11 - 12) opens.
Door open
→ both contacts in the open position, even with tampering with simple tools
Close door
→ Signalling contact (11 - 12) closes
Lock door
→ Apply voltage to coil (A1, A2)
1st actuator interlocked
2nd safety contact (21 - 22) closes
3-22
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
LS-S11-…MT-ZBZ
③
a
b
④
A1
US
A1
A2
A2
a
b
c
d
e
⑤
A1
A2
21
22
21
22
21
22
13
14
13
14
13
14
Door closed and
interlocked
→ Voltage on coil (A1, A2)
Safety contact (21 - 22) closed
Signalling contact (13 - 14) open
Releasing of door
→ Coil de-energized (A1, A2)
e.g. via zero-speed monitor,
Safety contact (21 - 22) opens
Door open
→ Only possible once it is released
Signalling contact (13 - 14) closes.
Door open
→ Safety contact (21 - 22) open
Signalling contact (13 - 14) closed
Close door
→ Signalling contact (13 - 14) opens
Lock door
→ Apply voltage to coil (A1, A2)
1st actuator interlocked
2nd safety contact (21 - 22) closes
Safety contact
Signalling contact
Interlocked
Released
Open
33
3-23
Eaton Wiring Manual 06/11
Pilot devices
LS-Titan® position switches
“Personnel protection” by monitoring of the protective mechanism
LSR…I(A) /TKG LSR…I(A)/TS
STOP
33
LSR…TKG, LSR…TS
Closed
Open
a Safety contact
b Signalling contact
a
b
21
22
21
22
13
14
13
14
Hinged protective cover
closed
→ Safety contact (21 - 22) closed
Signalling contact (13 - 14) open
Protective flap open
→ Safety contact (21 - 22) open
Signalling contact (13 - 14) closed
3-24
• Hinged protective
cover open
• LSR... disconnects
power
• No danger
Eaton Wiring Manual 06/11
LS, LSM
LS4…ZB
LS…ZB
LS…ZBZ
Standards
• IEC 60947-5-1
→ EN 50047
• Dimensions
• Fixing
dimensions
• Operating points
• Minimum IP65
• IEC 60947-5-1
→ EN 50041
• Dimensions
• Fixing
dimensions
• Operating points
• IP65
• IEC 60947-5-1
• IP65
• IEC 60947-5-1
• IP65
Suitable applications
• Also for use in
safety circuits, by
positive
operation and
positive opening
contacts
• Safety position
switches for
protection of
personnel
• with separate
operating
element for
protective covers
• Positive
operation and
positive opening
contacts
• Approval of
employers'
liability insurance
Association
• Safety position
switches for
protection of
personnel
• with separate
operating
element for
protective covers
• Positive
operation and
positive opening
contacts
• Approval of
employers'
liability insurance
Association
• Safety position
switches for
protection of
personnel
• with separate
operating
element for
protective covers
• Positive
operation and
positive opening
contacts
• electromagnetic
interlock
• Approval of
employers'
liability insurance
Association
Drive
Pilot devices
LS-Titan® position switches
• Rounded plunger
(centre fixing)
• Roller plunger
(centre fixing)
• Rotary lever
• Angled roller
lever
• Adjustable roller
lever
• Actuating rod
• Spring-rod
actuator
• Operating heads
adjustable in 90°
steps
• Coded actuating
element
• Operating head:
– Can be rotated
by 90°
– Can be
actuated from
both sides
• Actuating
element
– Convertible for
vertical and
horizontal
fixing
• With triple coding
• Coded actuating
element
• Operating head:
– Can be rotated
by 90°
– Can be
actuated from
four sides and
from above
• Coded actuating
element
• Operating head:
– Can be rotated
by 90°
– Can be
actuated from
four sides
33
3-25
Eaton Wiring Manual 06/11
Pilot devices
LSE-Titan® electronic position switches
Operating point variably adjustable
The operating point on electronic position
switches LSE-Titan is adjustable and
variable. Two high-speed and bounce-free
PNP switching outputs enable high
switching frequencies.
33
The position switch is overload as well as
conditionally short-circuit proof and has
snap-action switching performance. This
ensures a defined and reproduceable
switching point. The operating point lies in
the range from 0.5 to 5.5 mm
(as supplied = 3 mm).
Adjustment to a new operating point is
carried out as follows:
adjust
fix
Move the plunger from the original to the
new switch position. For this purpose,
press the setting pushbutton for 1 s. The
LED now flashes with a high pulse
frequency and the new operating point is
retentively set.
The LSE-11 and LSE-02 complete devices
can be used in safety-oriented
connections. They have the same function
as electromechanical position switches.
1s
LED
set
fmax F 2 N
set
Bauart geprüft
Functional
Note
This means that all the devices are also
suitable for safety applications designed
for personnel or process protection.
TÜV
Rheinland
Safety
Type approved
Contact travel diagram
LSE-11
+Ue
0 0.5
5.5 6.1
LSE-02
+Ue
0 0.5
Q1
electron.
Q1
0V
3-26
Q2
Q1
electron.
Q2
default = 3.0
Q1
0V
Q2
Q2
default = 3.0
5.5 6.1
Eaton Wiring Manual 06/11
Pilot devices
Analog electronic position switches
Two part no. are available:
• LSE-AI with current output,
• LSE-AU with voltage output.
Contact travel diagram
LSE-AI
I [mA]
20
Analog, mechanically actuated position
switches directly linked with the world of
automation
Analog position switches LSE-AI (4 to
20 mA) and LSE-AU (0 to 10 V) represent
another innovation in electronic position
switches. Using them, it is now possible for
the first time to monitor the actual position
of a flue gas valve or an actuator
continuously. The actual position is
converted in analog fashion into voltage
(0 to 10 V) or current (4 to 20 mA) and then
continuously signalled to the electronics.
Even objects of varying sizes or
thicknesses, such as brake shoes, can be
scanned and the results processed further.
4
S [%]
0
33
100
LSE-AU
U [V]
10
S [%]
0
100
Simple rotational-speed dependent control
systems of fan motors or smoke-venting
blowers signal the opening angle of the air
damper (e.g. 25, 50 or 75 %) and thus save
power and material wear. The analog
position switches also have a diagnosis
output for further processing of data. This
means that the safe status can be
monitored and analyzed at all times. The
position switch also has a self-test
function. The outputs Q1 and Q2 are
constantly scanned for overload,
short-circuit against 0 V and short-circuit
against +Ue.
3-27
Eaton Wiring Manual 06/11
Pilot devices
Analog electronic position switches
Connection diagram
+24 V (–15 / +20 %)
LSE-AI
+Ue
F 200 mA
diagnosis +Q2
4 – 20 mA
analog +Q1
33
0V
A
< 400 O
Q Ue
0V
+24 V (–15 / +20 %)
LSE-AU
+Ue
diagnosis +Q2
analog +Q1
F 200 mA
F 10 mA
0V
V
0V
3-28
0 V – 10 V
Q Ue
Eaton Wiring Manual 06/11
Pilot devices
Analog electronic position switches
Circuit symbol
Normal scenario
LSE-AI
LSE-AU
Q1
4 – 20 mA
0 – 10 V
Q2
≈ Ue
≈ Ue
LED
LED
33
LED
t
t
Fault scenario
LSE-AI
LSE-AU
Q1
0 mA
0V
Q2
0V
0V
LED
LED
LED
t
Reset
+Ue
t
+Ue
t
>1s
t
>1s
3-29
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
Inductive Sensors
Inductive sensors are used to detect metal
objects. The objects are detected through
an electromagnetic field.
33
Assembly parts
With the ability to detect at close range,
inductive proximity sensors are very useful
for precision measurement and inspection
applications.
How an inductive sensor works
Inductive sensors create an invisible high
frequency oscillation field. When metal
objects are brought into this field, this
oscillating field is affected. Each sensor
has a specific sensing range switch point
so that metal target detection is very
accurate and repeatable.
If a metal object is brought into the field
created by the sensor, this is interrupted
and causes a reduction in the current
flowing through the sensor coil (eddy
current damping). The detector circuit
senses this change and sends a signal via
the sensor output.
A metal object, or target, enters the
sensing field.
The sensor coil is a coil of wire typically
wound around a ferrite core. If you could
see the electromagnetic field created by it,
it would be cone shape. The target will
pass through this field. The ferrite core
3-30
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
shapes the field and the size of the coil
determines the sensing range.
The resonance circuit creates a high
frequency oscillation of the
electromagnetic field (between 100 Hz and
1 MHz). If a metal object is located in the
field, this causes a change in the magnetic
field oscillation.
This change creates an eddy current
which dampens the signal fed back to the
sensor coil.
The detector circuit senses the change
and switches ON at a particular set point
(amplitude). This ON signal generates a
signal to the solid-state output.
The output circuit remains active until the
target leaves the sensing field. The
oscillator responds with an increase in
amplitude, and when it reaches the
setpoint value, the detector circuit
switches OFF. The output returns to its
normal state.
Correction factors
Multiply the sensing distance by the factor
given below.
Target
object
Sensor size
4–8
mm
12
mm
18
mm
30
mm
Stainless
Steel 4001)
0.90
0.90
1.0
1.0
Stainless
Steel 3002)
0.65
0.70
0.70
0.75
Brass
0.35
0.45
0.45
0.45
Aluminium
0.35
0.40
0.45
0.40
Copper
0.30
0.25
0.35
0.30
1)
Stainless steel 400 series to ASTM
A240, martensitic or ferritic,
magnetizable.
2) Stainless steel 300 series to ASTM
A240, austenitic, non-magnetizable.
The index of stainless steels is provided in
EN 10088-1.
Material wire of the target object
The sensing ranges stated by the sensor
manufacturer are usually based upon
ferrite targets made of carbon-rolled steel
(IE FE 235) defined by ISO 630.
Sensing ranges to targets made of other
materials have to have a correction factor
applied as listed in the table below. To use
this table, multiply the sensing distance of
the device by the factor given below.
3-31
33
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
Capacitive sensors
Capacitive sensors are designed to detect
both metallic and nonmetallic targets. They
are ideally suited for liquid level control
and for sensing powdered or granulated
material.
33
Operation of the capacitive sensors
Capacitive sensors operate using a
capacitor. This consists of two metal plates
that are separated by an insulating
dielectric material. The function of this type
of sensor is based on dielectric
capacitance, which is the ability of a
dielectric to store an electrical charge.
• Capacitor
①
③
②
The distance between the plates
determines the ability of the capacitor to
store an electrical charge.
a Plates
b Switch
c Dielectric
If an object is put into the electrical field.
the capacitance of the capacitor changes.
This change is used to implement the on/off
switch function.
When this principle is applied to the
capacitive sensor, one capacitive plate is
part of the switch, the enclosure (the
sensor face) is the insulator. The target is
the other “plate”. Ground is the common
path.
Capacitive proximity sensors can detect
any target that has a dielectric constant
greater than air. Liquids have high
dielectric constants. Metal also makes a
good target.
3-32
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
• Capacitive sensor
Capacitive sensors consist essentially of
four basic elements:
solid and liquid materials is greater than
that for air.
• Sensor (Dielectric)
• Resonance circuit
• Detector circuit
• Output circuit.
As an object approaches the sensor, the
dielectric constant of the capacitor
changes. The oscillator circuit’s vibration
begins when feedback capacitance is
detected. This is just the opposite in the
inductive proximity sensor, where the
vibration is damped when the target is
present.
Objects made of non-conductive materials
affect the active surface of a capacitive
proximity switch in the same way. The
coupling capacitance is increased.
Materials with a high dielectric constant
achieve great switching distances.
Notes
When scanning organic materials (wood,
grain, etc.) it must be noted that the
attainable switching distance is greatly
dependent on their moisture content.
(εWater = 80!)
Effects
Capacitive sensors are activated both by
conductive as well as non-conductive
objects.
Metals achieve the greatest switching
distances due to their high conductivity.
Derating factors for various metals, such
as are necessary with inductive sensors,
need not be taken into account.
Actuation by objects made of
non-conductive materials (insulators):
When an insulator is brought between the
electrodes of a capacitor, the capacitance
rises relative to the dielectric constant e of
the insulator. The dielectric constant for all
3-33
33
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
Influence of environmental conditions
As can be seen from the following diagram,
the switching distance Sr is dependent on
the dielectric constant εr of the object to
be monitored.
33
Metal objects produce the maximum
switching distance (100 %).
With other materials, it is reduced relative
to the dielectric constant of the object to be
monitored.
80
er
60
30
10
1
10 20
40
60
80
100
sr [%]
The following table lists the dielectric
constants εr of some important materials.
Due to the high dielectric value of water,
the fluctuations with wood can be
significant. Damp wood therefore is
registered much more effectively by
capacitive sensors than dry wood.
3-34
Material
εr
Air, vacuum
Teflon
Wood
Paraffin
Kerosene
Oil of terpentine
Transformer oil
Paper
Polyethylene
Polypropylene
Cable insulation
Soft rubber
Silicone rubber
Polyvinyl chloride
Polystyrene
Celluloid
Perspex
Araldite
Bakelite
Silica glass
Hard rubber
Oil-impregnated paper
Chipboard
Porcelain
Laminated paper
Quartz sand
Glass
Polyamide
Mica
Marble
Alcohol
water
1
2
2-7
2.2
2.2
2.2
2.2
2.3
2.3
2.3
2.5
2.5
2.8
2.9
3
3
3.2
3.6
3.6
3.7
4
4
4
4.4
4.5
4.5
5
5
6
8
25.8
80
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
Optical sensors
Operating principle of the optical sensor
A LED sends a beam of light, which is
picked up by a photodetector. An object is
detected when it passes between the LED
and photodetector, interrupting the light
beam.
Optical sensors use light to detect the
presence or absence of an object. The
main advantages of optical sensors are
contactless sensing of objects and greatly
extended sensing ranges.
Let’s look at how an optical sensor works.
①
②
③
④
⑤
⑥
⑤
⑩
⑨
⑧
a Power supply:
Feeds the sensor circuit with a
regulated DC voltage.
b Modulator:
generates pulses to cycle amplifier and
LED at desired frequency.
c Source current amplifier
d LED
e Lens
f Target object or reflector
g Photodetector:
Either a photodiode or a phototransistor
device, selected for a maximum
sensitivity at the source LED’s emitted
light wave-length. Both the source LED
and the detector have protective
lenses. When the sensor picks up the
⑦
light, it sends a small amount of current
to the detector amplifier.
h Detector Amplifier:
Blocks current generated by the
background light. It also provides
amplification of the signal received to a
usable level, and sends it through to the
demodulator.
i Demodulator:
Sorts out the light thrown out by the
sensor from all other light in the area. If
the demodulator decides the signals it
receive are okay, it signals the output.
j Output:
Performs switching routine when
directed to do so by the demodulator.
3-35
33
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Functionality
Detection methods
Operating Mode
Description
Operating Mode
Light barriers
A source unit in
one location
sends a light
beam to a
detector unit in
another
location. An
object is
detected when it
passes between
the source unit
and the detector
unit, interrupting
the light beam.
Reflected-light beam
Light source and
receiver are
located in the
same unit. If a
target moves in
front of the
optical sensor, a
reflector
reflects the light
beam directly
back to the
receiver.
Background rejection
(Perfect Prox)
Target
33
Detector
Source
Polarisation reflex sensor
Target
Retroreflector
Reflex
Sensor
3-36
Description
Target
Reflex
Sensor
Light source and
receiver are
located in the
same unit. If a
target moves in
front of the optical
sensor, it reflects
the light beam
directly back to the
receiver.
This is a special
type of diffuse
reflective sensor
that includes two
detectors. This
Target
sensor offers
reliable detection
of target objects in
Background a defined sensing
range and at the
Fixed Focus
same time ignores
Perfect Prox
objects outside of
Sensor
this range. Unlike a
standard diffuse
reflective optical
sensor, color or
reflectivity has
minimal effect on
the sensing range
of this sensor.
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Broken Tool Detection
Description
Catalog Number
E58 Perfect Prox Sensor
E58-30DP or E58-18DP Sensor
This sensor is used to sense for the
presence of the bit on a mill. The high
sensing power and background
suppression of the Perfect Prox allows
reliable detection through high levels of
cutting fluids, while ignoring objects just
beyond the bit. The rugged harsh duty
sensor survives constant exposure to
lubricants, cutting fluids and flying metal
chips.
33
Broken Tool Detection
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A tubular sensor is used to detect the
presence of a drill bit – should the drill bit
be broken the sensor would signal a
controller.
3-37
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Machining process
33
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A ferrous only sensor is used in a process
where aluminum is being machined. The
ferrous only sensor ignores the aluminum
(non-ferrous) chips from the machining
process and only detects the ferrous
target.
Tool Position
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A tubular sensor is used to detect the
position of a tool chuck.
3-38
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Bottle Filling Detection
Description
Catalog Number
E65 Clear Object Sensor
E71-CON or E71-COP
A clear object sensor is used to sense the
presence of bottles at a filling operation.
The sensor offers high reliability in sensing
clear bottles of different colors and
thicknesses.
33
Process control engineering
Description
Catalog Number
Tubular capacitive Sensor
E53 Product Family
A capacitive sensor used to verify fill level
of bottled water on a filling process line.
3-39
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Conveyor System Control
33
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A tubular inductive sensor is used to detect
the presence of metal carriers holding
parts to be machined.
Stack Height Control
Description
Catalog Number
Comet Series Thru-Beam - source
11100A
Comet Series Thru-beam - detector
12100A
A set of thru-beam sensors determines the
height of a scissor lift. For example, when
the control is set for “dark-to-light”
energize, the lift rises after a layer has
been removed and stops when the next
layer breaks the beam again.
3-40
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Carton Fill-Level Detection
Description
Catalog Number
Comet visible reflex photoelectric sensor
14102A
Comet reflected-light beam with
background suppression (Perfect Prox)
13103A
Retro-reflector
6200A-6501
33
Two sensors work together to inspect the
fill level in cartons on a conveyor. A reflex
sensor senses the position of the carton
and energizes the sensors located over the
contents. If the sensor does not “see” the
fill level, the carton does not pass
inspection.
Lid Detection
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
Two sensors are used to detect a can on a
conveyor belt and to check whether it has
a cover.
3-41
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Tollbooth Control
33
Description
Catalog Number
E67 Perfect Prox long range sensor
E67-LRDP
The long range polarized reflex controls
are used for the time control of a toll
barrier. As soon as the car that has paid
passes, the barrier closes in order to
ensure that the next car stops. With the
initiator E67 Long Range Perfect Prox you
can mount the sensor on just one side
instead of both. It detects cars with
different colors and finishes whilst reliably
ignoring all other background objects.
The rugged design makes it also suitable
for continuous operation in extreme
weather conditions.
Liquid Level Detection
Description
Catalog Number
Tubular capacitive Sensor
E53 Product Family
A pair of capacitive sensors are used to
sense high and low liquid levels in a tank
through a sight glass. This arrangement
starts a pump to fill the tank when the lower
sensor is energized and shuts the pump off
when the top sensor is energized.
3-42
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Bulk Material Detection
Description
Catalog Number
Tubular capacitive Sensor
E53 Product Family
A capacitive sensor is used to control fill
level of solids such as plastic pellets in a
hopper or bin.
33
Parts Presence
Description
Catalog Number
Limit switch, inductive sensor
E57 Product Family
Comet Perfect Prox
1310
Inductive sensor iProx
E59-M
A sensor configured as a limit switch can
be used to detect whether a component is
present in an automatic assembly
machine. The Comet detects all materials,
colors and services and masks out the
background. The iProx can be programmed
to detect a particular material and thus to
ignore all other materials.
3-43
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Parts Presence
33
Description
Catalog Number
Comet reflected-light beam
(Perfect Prox), 100 mm
13101A
The sensor detects components with
different heights from approx. 13 to 76 mm
in a channel and can mask out the channel.
Installation is simple and does not require
any drilling or cutting of the channel.
Filter Paper Length Control
Description
Catalog Number
A focused diffuse Comet reflective
sensor
13102A
A focused diffuse reflective sensor
interfaces with a programmable controller
to measure a specific length of corrugated
automotive filter paper. The controller
detects the presence or absence of a
corrugation. When a predetermined
number of corrugations has been detected,
the programmable controller directs a
shear to cut the paper.
3-44
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Speed monitoring
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A tubular sensor is used to detect the
presence of set screws on a shaft hub
providing a control device with signals for
speed regulation or detection of rotation.
33
Motion Control
Description
Catalog Number
Tubular inductive sensor
E57 Product Family or iProx
A pair of tubular sensors is used to
determine full open and fully closed valve
position.
3-45
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Clear Plastic Web Break Detection
33
Description
Catalog Number
Comet series 150 mm diffuse focus
reflective light sensor
13107A
The clear web is detected by an extremely
sensitive diffuse reflective sensor. Its short
detection range makes it immune to
reflective objects in the background. The
extremely high excess gain helps it ignore
reflection caused by fluttering of the web.
Paper detection
Description
Catalog Number
Comet Perfect Prox, 50 mm series,
right angled
13104R
Right angle viewing and compact size
allow the sensor to be mounted in the tight
confines of paper handling systems. High
resolution and sharp optical cut-off ensure
that background machinery will be ignored
while paper will be detected regardless of
color and texture.
a
b
c
a Comet sensors
b Paper
c Roller
3-46
Eaton Wiring Manual 06/11
Pilot devices
Sensors – Applications
Damage Warning
Description
Catalog Number
Comet E58 series Thru-Beam, Source
E58-30TS
Thru-beam sensor E58 series, detector
E58-30TD
33
Source and detector are mounted at
opposite ends of a long warehouse storage
shelf with the beam situated a safe
distance below overhead obstacles
(lighting, cable ducts, gas lines, etc.). If a
forklift operator interrupts the beam while
moving a load, a siren or flashing light will
warn him to stop before any damage
occurs.
3-47
Eaton Wiring Manual 06/11
Notes
33
3-48